Determining The Movement Profile Of An Armature In A Magnet

Abstract

A method and a device determine a movement profile of a solenoid plunger in a solenoid for monitoring a plunger-type armature movement for changes. The solenoid is an electromagnet in which a magnetic field can be generated by an electrical coil and a measuring unit is connected to the electrical coil. The method includes measuring a current profile with respect to time when the solenoid is operated, examining a measured current profile with respect to time for a position of a first reversal point in respect of time after operation of the solenoid and a current intensity, and assigning the position of the first reversal point to a movement end of the plunger-type armature.

Description

The invention relates to a method and to an apparatus for determining the movement profile of a plunger-type armature in a solenoid.

In solenoids, also called linear solenoids, the internal mechanical friction between the bearing of the solenoid and the plunger-type armature, which is also called a plunger-type core, changes. The cause of the change in the internal mechanical friction is based, amongst other things, on mechanical wear, soiling in the bearing and/or external magnetic fields. As a result of these changes, the movement sequence of the plunger-type armature and therefore the force provided by the solenoid comprising the plunger-type armature change. A problem is encountered, in particular, when an increase in the internal mechanical friction leads to prolonging of the movement sequence of the plunger-type armature and/or to a reduction in the force which is provided by the plunger-type armature.

In the prior art, changes in the movement sequence of the plunger-type armature are usually identified by additional movement sensors and/or end contacts.

An evaluation unit then monitors the time period from when the solenoid is switched on to the point at which the end position of the plunger-type armature is released and then compares the measured value with a prespecified setpoint value. The evaluation unit can then generate an error message when there is a predefined deviation from the prespecified setpoint value.

The object of the invention, then, is to provide a more expedient and more reliable method for determining the movement profile of a plunger-type armature in a solenoid and/or for identifying the increase in mechanical friction between the bearing and the plunger-type armature, which method manages, in particular, without additional end contacts or movement sensors.

This object is achieved in accordance with the method as claimed in claim 1, the switch as claimed in claim 10 and the switchgear installation as claimed in claim 11.

The invention proposes a method for determining the movement profile of a plunger-type armature in a solenoid, that is to say also for the purpose of monitoring the plunger-type armature movement for changes, wherein the solenoid is an electromagnet in which the magnetic field can be generated by means of an electrical coil, wherein a measuring unit is connected to the electrical coil, wherein the current profile with respect to time is measured when the solenoid is operated, the measured current profile with respect to time is examined for the position of a first reversal point in respect of time after operation of the solenoid and the current intensity, and wherein the position of the first reversal point in the measured current profile with respect to time is assigned to the movement end of the plunger-type armature and/or describes said movement end.

A method for determining the movement profile of a plunger-type armature in a solenoid is also preferred, wherein the measured current profile is examined for the position of a first local maximum of the current, the measured current profile is examined for the position of a second local maximum of the current, and the measured current profile is examined for the position of a first reversal point between the first local maximum and the second local maximum, and wherein the position of the first reversal point is assigned to the movement end of the plunger-type armature and/or describes said movement end.

It is also preferred that the position of the first reversal point is compared with a reference position.

It is further preferred that a shift in the position of the first reversal point toward longer times after operation of the solenoid is assessed as a slowdown of the movement of the plunger-type armature in comparison to the reference position.

It is also preferred that a shift in the position of the first reversal point toward larger current intensities is assessed as an increase in friction losses in comparison to the reference position.

It is also preferred that the reference position of the reversal point can be defined by a reference measurement, and that, in subsequent operations of the solenoid, the position of the first reversal point is determined and compared with the reference position of the reversal point.

It is further preferred that a fault signal is generated by the measuring unit when the position of the first reversal point deviates from the reference position of the reversal point by a predetermined or predeterminable time.

It is also preferred that the method for determining the movement profile of a plunger-type armature in a solenoid is employed in a medium-voltage and/or high-voltage switchgear installation.

It is also preferred that the method for determining the movement profile of a plunger-type armature in a solenoid is used in a medium-voltage and/or high-voltage switchgear installation and the fault signal which is generated by the measuring unit triggers a warning message and/or fault message at the switchgear installation.

A medium-voltage and/or high-voltage switch, in particular a vacuum switch, comprising a solenoid and a plunger-type armature for triggering a switching movement is also preferred, wherein the movement profile of the plunger-type armature is determined in accordance with one of the above-described methods.

A medium-voltage and/or high-voltage switchgear installation comprising a solenoid and a plunger-type armature for triggering a switching movement is further preferred, wherein the movement profile of the plunger-type armature is determined in accordance with one of the above-described methods.

It is further preferred that the switchgear installation has a communication unit which is connected to the measuring unit and the communication unit is designed to transmit the position of the first reversal point and/or of the first reversal point in relation to the reference position of the first reversal point and/or the fault signal to a further communication unit.

In particular, it is also preferred that the further communication unit is connected to a control center which receives the position of the first reversal point and/or the position of the first reversal point in relation to the reference position of the first reversal point and/or the fault signal and generates a corresponding warning message.

The subject matter of the invention will be explained in more detail below with reference to a FIGURE:

FIG. 1: illustration of the time profile of the current after operation of the solenoid.

FIG. 1 shows the time profile of the current after operation of the solenoid. In FIG. 1, the amplitude A of the current is plotted with respect to time t, wherein, for example, the amplitude A is illustrated in arbitrary units and the time t is illustrated in ms here. Said FIGURE shows four current profiles, wherein the current profile a corresponds to a reference measurement and has a first local maximum 2, a first reversal point 1, also called the reference position or reference position of the first reversal point, and a second local maximum 3.

Here, the reversal point 1 indicates the movement end of the plunger-type armature.

The current profile b shows a current profile in the event of increased friction between the bearing of the solenoid and the plunger-type armature of the solenoid. The current profile b has, in comparison to the current profile a, a reversal point 1′ which is shifted in respect of time toward a longer time after operation of the solenoid, and has an increased amplitude of the current at the reversal point 1′.

The current profile c shows a current profile in the event of friction between the bearing of the solenoid and the plunger-type armature of the solenoid, which friction is increased in relation to the current profiles a and b. The reversal point 1″ is shifted toward a longer time and toward a higher amplitude of the current intensity in relation to the reversal points of the current profiles a and b.

The current profile d shows the current profile after operation of the solenoid with a greatly increased friction between the bearing of the solenoid and the plunger-type armature of the solenoid. The reversal point 1′″ of the current profile d is shifted significantly toward longer times and toward higher currents.

It should be noted that, even in the case of the current profiles a, b, c and d, the second maximum 3, 3′, 3″, 3′″ is shifted toward longer times as the friction between the bearing of the solenoid and the plunger-type armature of the solenoid increases.

Therefore, the current profiles can be used to perform a functional check which identifies a changed movement sequence of the plunger-type armature in the solenoid and/or a changed friction between the bearing of the solenoid and the plunger-type armature of the solenoid.

Claims

1-12. (canceled)

13. A method for determining a movement profile of a plunger-type armature in a solenoid for monitoring a plunger-type armature movement for changes, the solenoid being an electromagnet in which a magnetic field can be generated by means of an electrical coil, and a measuring unit is connected to the electrical coil, which comprises the steps of:

measuring a current profile with respect to time when the solenoid is operated;

examining a measured current profile with respect to time for a position of a first reversal point in respect of the time after operation of the solenoid and a current intensity; and

assigning the position of the first reversal point to a movement end of the plunger-type armature.

14. The method for determining the movement profile of the plunger-type armature in the solenoid according to claim 13, which further comprises:

examining the measured current profile for a position of a first local maximum of a current;

examining the measured current profile for a position of a second local maximum of the current;

examining the measured current profile for the position of the first reversal point between the first local maximum and the second local maximum; and

assigning the position of the first reversal point to the movement end of the plunger-type armature.

15. The method for determining the movement profile of the plunger-type armature in the solenoid according to claim 13, which further comprises comparing the position of the first reversal point with a reference position.

16. The method for determining the movement profile of the plunger-type armature in the solenoid according to claim 15, wherein a shift in the position of the first reversal point toward longer times after operation of the solenoid is assessed as a slowdown of a movement of the plunger-type armature in comparison to the reference position.

17. The method for determining the movement profile of the plunger-type armature in the solenoid according to claim 16, wherein a shift in the position of the first reversal point toward larger current intensities is assessed as an increase in friction losses in comparison to the reference position.

18. The method for determining the movement profile of the plunger-type armature in the solenoid according to claim 15, wherein the reference position of the reversal point can be defined by a reference measurement, and in that, in subsequent operations of the solenoid, the position of the first reversal point is determined and compared with the reference position of the reversal point.

19. The method for determining the movement profile of the plunger-type armature in the solenoid according to claim 18, which further comprises generating a fault signal via the measuring unit when the position of the first reversal point deviates from the reference position of the reversal point by a predetermined or predeterminable time.

20. The method for determining the movement profile of the plunger-type armature in the solenoid according to claim 19, which further comprises determining the movement profile in a medium-voltage and/or high-voltage switchgear installation.

21. The method for determining the movement profile of the plunger-type armature in the solenoid according to claim 19, which further comprises determining the movement profile in a medium-voltage and/or high-voltage switchgear installation and that the fault signal which is generated by the measuring unit triggers a warning message and/or fault message at the switchgear installation.

22. A medium-voltage and/or high-voltage switch, comprising:

a solenoid having an electrical coil, an electromagnet in which a magnetic field can be generated by means of said electrical coil, and a measuring unit connected to said electrical coil;

a plunger-type armature for triggering a switching movement, wherein a movement profile of said plunger-type armature is determined by: measuring a current profile with respect to time when said solenoid is operated; examining a measured current profile with respect to time for a position of a first reversal point in respect of time after operation of said solenoid and a current intensity; and assigning the position of the first reversal point to a movement end of said plunger-type armature.

23. A medium-voltage and/or high-voltage switchgear installation, comprising:

a solenoid having an electrical coil, an electromagnet in which a magnetic field can be generated by means of said electrical coil, and a measuring unit connected to said electrical coil;

a plunger-type armature for triggering a switching movement, wherein a movement profile of said plunger-type armature is determined by: measuring a current profile with respect to time when said solenoid is operated; examining a measured current profile with respect to time for a position of a first reversal point in respect of time after operation of said solenoid and a current intensity; and assigning the position of the first reversal point to a movement end of said plunger-type armature.

24. The medium-voltage and/or high-voltage switchgear installation according to claim 23, further comprising a communication unit which is connected to said measuring unit and said communication unit is configured to transmit the position of the first reversal point and/or the position of the first reversal point in relation to a reference position of the first reversal point and/or a fault signal to a further communication unit.